Overexpressed Cav{beta}3 Inhibits N-type (Cav2.2) Calcium Channel Currents through a Hyperpolarizing Shift of "Ultra-slow" and "Closed-state" Inactivation

doi:10.1085/jgp.200308967

Published online 15 March 2004 doi:10.1085/jgp.200308967
The Rockefeller University Press, 0022-1295 $8.00
JGP, Volume 123, Number 4, 401-416

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Overexpressed Ca_vß3 Inhibits N-type (Ca_v2.2) Calcium Channel Currents through a Hyperpolarizing Shift of "Ultra-slow" and "Closed-state" Inactivation

Takahiro Yasuda¹, Richard J. Lewis¹^,2, and David J. Adams¹

¹ School of Biomedical Sciences, The University of Queensland, Queensland 4072, Australia
² Institute for Molecular Bioscience, The University of Queensland, Queensland 4072, Australia

Address correspondence to David J. Adams School of Biomedical Sciences, The University of Queensland, Queensland 4072, Australia. Fax: (07) 3365-4933; email: dadams{at}uq.edu.au

It has been shown that ß auxiliary subunits increasecurrent amplitude in voltage-dependent calcium channels. Inthis study, however, we found a novel inhibitory effect of ß3subunit on macroscopic Ba²⁺ currents through recombinant N-and R-type calcium channels expressed in Xenopus oocytes. Overexpressedß3 (12.5 ng/cell cRNA) significantly suppressed N-and R-type, but not L-type, calcium channel currents at "physiological"holding potentials (HPs) of -60 and -80 mV. At a HP of -80 mV,coinjection of various concentrations (0–12.5 ng) of theß3 with Ca_v2.2 ${alpha}$ ₁ and ${alpha}$ ₂ ${delta}$ enhanced the maximum conductanceof expressed channels at lower ß3 concentrations butat higher concentrations (>2.5 ng/cell) caused a marked inhibition.The ß3-induced current suppression was reversed ata HP of -120 mV, suggesting that the inhibition was voltagedependent. A high concentration of Ba²⁺ (40 mM) as a chargecarrier also largely diminished the effect of ß3 at-80 mV. Therefore, experimental conditions (HP, divalent cationconcentration, and ß3 subunit concentration) approachingnormal physiological conditions were critical to elucidate thefull extent of this novel ß3 effect. Steady-stateinactivation curves revealed that N-type channels exhibited"closed-state" inactivation without ß3, and that ß3caused an $~$ 40-mV negative shift of the inactivation, producinga second component with an inactivation midpoint of approximately-85 mV. The inactivation of N-type channels in the presenceof a high concentration (12.5 ng/cell) of ß3 developedslowly and the time-dependent inactivation curve was best fitby the sum of two exponential functions with time constantsof 14 s and 8.8 min at -80 mV. Similar "ultra-slow" inactivationwas observed for N-type channels without ß3. Thus,ß3 can have a profound negative regulatory effecton N-type (and also R-type) calcium channels by causing a hyperpolarizingshift of the inactivation without affecting "ultra-slow" and"closed-state" inactivation properties.

Key Words: voltage-dependent calcium channel • Xenopus oocyte • ß3 auxiliary subunit • negative regulation • voltage-dependent inactivation

Abbreviations used in this paper: AID, ${alpha}$ ₁ subunit interactiondomain; HP, holding potential; HVI, high-voltage inactivation;LVI, low-voltage inactivation; VDCC, voltage-dependent calciumchannel.

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